Summary An Air Canada AirbusA330-300, C-GFAF, was parked at Vancouver International Airport while the crew prepared the aircraft for boarding. A fault in the cabin entertainment system had been reported and a technician was in the passenger cabin, resetting the system in accordance with normal procedures. Shortly thereafter, the in-charge flight attendant observed a fire in the video system management unit (SMU), located in the forward galley area of the cabin. The technician used the main power switch to remove power from the cabin entertainment system; however, smoke continued to emanate from the SMU. The technician then removed power from the entire aircraft and discharged a halon fire extinguisher into the SMU to extinguish the fire. Airport emergency response personnel were alerted and responded promptly. Fire damage was contained within the SMU and there were no injuries. Maintenance personnel removed the SMU and the aircraft departed without further incident. Ce rapport est galement disponible en franais. Other Factual Information The P@ssport TM cabin entertainment system on the aircraft was manufactured by Rockwell Collins Inc. The system comprised the video system management unit (SMU), part numberRV970-0029-005, and approximately 20other main components. The subject SMU, serial number2006, was installed in the occurrence aircraft on 04January2002 after being repaired by the manufacturer. It subsequently operated for approximately 169hours before the occurrence. The SMU was installed in the video control centre (VCC) in the forward galley area of the aircraft. The VCC received 115-volt aircraft power, and an internal power supply produced other voltages required by the system. The cabin entertainment system was normally turned on and off by cabin crew using a touch-sensitive screen. To turn off the system in an emergency, a main power switch located in the VCC is used. However, the SMU and two other components continued to be powered for up to 120seconds by two 6-volt, 4.5amp hour batteries, as the SMU completes a systematic software shutdown. Battery power is provided to these components regardless of the position of the cabin entertainment system main power switch or the availability of aircraft power. The SMU was removed from the aircraft after the occurrence and inspected. The outside of the SMU case was not damaged. The tamper-proof seal was intact and the rear electrical connector pins were clean with no indication of pitting, arcing, or heat damage. Inside the SMU case, the fan assembly for the central processing unit (CPU), on the processor board, was detached from the CPU. One of two plastic locking tabs was thermally deformed, allowing the fan to separate from the CPU. Burn patterns on the back of the fan assembly were consistent with the fan being attached to the CPU while the fire was in progress. Components on the processor board adjacent to the CPU, and both faces of the processor board itself, had extensive heat damage. One of these components, a switching regulator integrated circuit (U18), received 12-volt power via a copper trace on the processor board. The copper trace exhibited signs of overheating, which were consistent with exposure to a high electrical current, particularly in the vicinity of the U18 switching regulator. A resettable fuse and two small capacitors, originally mounted on the processor board, had fallen onto the SMU mother board. The solder that held these components to the processor board had melted and all three components exhibited heat damage. The resettable fuse had thermally tripped. An integrated circuit (U19) on the processor board will detect a short circuit condition external to the U18 switching regulator and remove power from the component; however, an internal failure within the U18 switching regulator will not be detected. The SMU, including the processor board, is normally powered by the SMU power supply. The voltage output of the SMU power supply is monitored and the power supply will shut down if an over-voltage condition is detected. The SMU power supply was tested after the occurrence and functioned normally. The backup batteries and the copper trace that deliver 12-volt power to the U18 switching regulator are not protected against over-current conditions. Burn tests were conducted on similar electrical components in an attempt to replicate the heat damage to components on the occurrence processor board. The components did not exhibit the extensive damage observed on the SMU processor board after being exposed to a direct flame for approximately one minute. According to the manufacturer, a component failure on the processor board will typically produce high heat for less than one second. The SMU had been repaired by Rockwell Collins on 01October, 08November and 06December2001. During the repairs in October the processor board, which includes the U18 switching regulator, was replaced. In November, the SMU was returned to Rockwell Collins after it had begun to smoke during installation. The SMU was again returned to Rockwell Collins in December, after it was installed in an aircraft but failed to operate. In December, repair technicians discovered that the U18 switching regulator was burnt. The processor board was again replaced and operated until the occurrence on 17January2002. Rockwell Collins subsequently identified a manufacturing process deficiency for U18 components manufactured before July2000. The manufacturing deficiency resulted in an incomplete seal around the U18 component, allowing contaminants to penetrate the plastic case and creating an environment conducive to premature component failure. The U18 component on the damaged processor board had been manufactured in1999. U18 is common to 11other processor boards in each P@ssport entertainment system. In total, 539of these processor boards are in the P@ssport entertainment systems of 27aircraft operating worldwide. Most failures of electronic components occur within the first few weeks of operation. Manufacturers of aircraft electronics typically subject new components to a burn-in1 period prior to installation, to increase the reliability of the finished product and identify any manufacturing deficiencies. The SMU was subject to a burn-in period when it was initially manufactured. Spare SMU electrical components, however, including the processor board, are not subject to a burn-in period. On 27 August 2001, the Federal Aviation Administration (FAA) of the United States of America issued a series of airworthiness directives2 (AD) that apply to aircraft with entertainment systems which cannot be completely powered off. The AD ensured that the main power switch in the VCC removes electrical power from all entertainment system components. This FAA AD series, however, does not apply to the P@ssport entertainment system and, with respect to Airbus aircraft, only to the A340-211model. On 07 December 2001, Airbus issued a service bulletin (SB-A340-23-4119), similar to the FAA AD, modifying the in-flight entertainment systems on all A340-313aircraft. This SB ensured that the main power switch in the VCC removes electrical power from all entertainment system components. This SB, however, applies only to the A340-313model and one specific entertainment system: it does not apply to other Airbus aircraft or the P@ssport entertainment system.